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Five-Minute Check (over Lesson 2-3) Then/Now New Vocabulary
Key Concept: Rational Zero Theorem Example 1: Leading Coefficient Equal to 1 Example 2: Leading Coefficient not Equal to 1 Example 3: Real-World Example: Solve a Polynomial Equation Key Concept: Upper and Lower Bound Tests Example 4: Use the Upper and Lower Bound Tests Key Concept: Descartes’ Rule of Signs Example 5: Use Descartes’ Rule of Signs Key Concept: Fundamental Theorem of Algebra Key Concept: Linear Factorization Theorem Example 6: Find a Polynomial Function Given Its Zeros Key Concept: Factoring Polynomial Functions Over the Reals Example 7: Factor and Find the Zeros of a Polynomial Function Example 8: Find the Zeros of a Polynomial When One is Known Lesson Menu
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Divide (2x4 – 3x3 – 13x2 + 36x – 45) ÷ (2x – 5) using long division.
A. B. C. D. 5–Minute Check 1
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Find (x3 + 2x2 – 5x – 6) ÷ (x – 2) using synthetic division.
A. B. x2 + 4x + 3 C. D. x2 – 4x + 1 5–Minute Check 2
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Find (x4 – x3 + 2x + 5) ÷ (x + 2) using synthetic division.
A. B. C. D. 5–Minute Check 3
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A. yes, no; f(x) = (x – 2)(x 3 – 9x + 14)
Use the Factor Theorem to determine if (x – 2) and (x + 1) are factors of f (x) = x4 – 2x3 – 9x2 + 32x – 28. Use the binomials that are factors to write a factored form of f (x). A. yes, no; f(x) = (x – 2)(x 3 – 9x + 14) B. no, yes; f(x) = (x + 1)(x 3 – 3x 2 – 6x + 28) C. yes, no; f(x) = (x – 2)2(x – 7) D. yes, yes; f(x) = (x – 2)(x + 1)(x 2 + x – 8) 5–Minute Check 4
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Find f (3) using synthetic substitution if f (x) = x 6 – 5x 5 + 6x 4 + 4x 3 + 12x 2 + 8.
A. –2422 B. 8 C. 80 D. 224 5–Minute Check 5
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Divide (2x4 – 3x3 – 13x2 + 36x – 45) ÷ (2x – 5) using long division.
A. B. C. D. 5–Minute Check 1
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Find (x3 + 2x2 – 5x – 6) ÷ (x – 2) using synthetic division.
A. B. x2 + 4x + 3 C. D. x2 – 4x + 1 5–Minute Check 2
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Find (x4 – x3 + 2x + 5) ÷ (x + 2) using synthetic division.
A. B. C. D. 5–Minute Check 3
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A. yes, no; f(x) = (x – 2)(x 3 – 9x + 14)
Use the Factor Theorem to determine if (x – 2) and (x + 1) are factors of f (x) = x4 – 2x3 – 9x2 + 32x – 28. Use the binomials that are factors to write a factored form of f (x). A. yes, no; f(x) = (x – 2)(x 3 – 9x + 14) B. no, yes; f(x) = (x + 1)(x 3 – 3x 2 – 6x + 28) C. yes, no; f(x) = (x – 2)2(x – 7) D. yes, yes; f(x) = (x – 2)(x + 1)(x 2 + x – 8) 5–Minute Check 4
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Find f (3) using synthetic substitution if f (x) = x 6 – 5x 5 + 6x 4 + 4x 3 + 12x 2 + 8.
A. –2422 B. 8 C. 80 D. 224 5–Minute Check 5
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Find real zeros of polynomial functions.
You learned that a polynomial function of degree n can have at most n real zeros. (Lesson 2-1) Find real zeros of polynomial functions. Find complex zeros of polynomial functions. Then/Now
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Descartes’ Rule of Signs Fundamental Theorem of Algebra
Rational Zero Theorem lower bound upper bound Descartes’ Rule of Signs Fundamental Theorem of Algebra Linear Factorization Theorem Conjugate Root Theorem complex conjugates irreducible over the reals Vocabulary
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Key Concept 1
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Step 1 Identify possible rational zeros.
Leading Coefficient Equal to 1 A. List all possible rational zeros of f (x) = x3 – 3x2 – 2x + 4. Then determine which, if any, are zeros. Step 1 Identify possible rational zeros. Because the leading coefficient is 1, the possible rational zeros are the integer factors of the constant term 4. Therefore, the possible rational zeros are ±1, ± 2, and ± 4. Example 1
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Step 2 Use direct substitution to test each possible zero.
Leading Coefficient Equal to 1 Step 2 Use direct substitution to test each possible zero. f(1) = (1)3 – 3(1)2 – 2(1) + 4 or 0 f(–1) = (–1)3 – 3(–1)2 – 2(–1) + 4 or 2 f(2) = (2)3 – 3(2)2 – 2(2) + 4 or –4 f(–2) = (–2)3 – 3(–2)2 – 2(–2) + 4 or –12 f(4) = (4)3 – 3(4)2 – 2(4) + 4 or 12 f(–4) = (–4)3 – 3(–4)2 – 2(–4) + 4 or –100 The only rational zero is 1. Answer: Example 1
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Step 2 Use direct substitution to test each possible zero.
Leading Coefficient Equal to 1 Step 2 Use direct substitution to test each possible zero. f(1) = (1)3 – 3(1)2 – 2(1) + 4 or 0 f(–1) = (–1)3 – 3(–1)2 – 2(–1) + 4 or 2 f(2) = (2)3 – 3(2)2 – 2(2) + 4 or –4 f(–2) = (–2)3 – 3(–2)2 – 2(–2) + 4 or –12 f(4) = (4)3 – 3(4)2 – 2(4) + 4 or 12 f(–4) = (–4)3 – 3(–4)2 – 2(–4) + 4 or –100 The only rational zero is 1. Answer: ±1, ± 2, ± 4; 1 Example 1
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Leading Coefficient Equal to 1
B. List all possible rational zeros of f (x) = x 3 – 2x – 1. Then determine which, if any, are zeros. Step 1 Because the leading coefficient is 1, the possible rational zeros are the integer factors of the constant term –1. Therefore, the possible rational zeros of f are 1 and –1. Example 1
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Step 2 Begin by testing 1 and –1 using synthetic substitution.
Leading Coefficient Equal to 1 Step 2 Begin by testing 1 and –1 using synthetic substitution. –2 –1 1 1 –1 1 1 –1 –2 –1 1 0 –2 –1 –1 1 1 1 –1 –1 0 Example 1
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Leading Coefficient Equal to 1
Because f (–1) = 0, you can conclude that x = –1 is a zero of f. Thus f (x) = (x + 1)(x 2 – x – 1). Because the factor x 2 – x – 1 yields no rational zeros, we can conclude that f has only one rational zero, x = –1. Answer: Example 1
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Leading Coefficient Equal to 1
Because f (–1) = 0, you can conclude that x = –1 is a zero of f. Thus f (x) = (x + 1)(x 2 – x – 1). Because the factor x 2 – x – 1 yields no rational zeros, we can conclude that f has only one rational zero, x = –1. Answer: ±1; 1 Example 1
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List all possible rational zeros of f (x) = x 4 – 12x 2 – 15x – 4
List all possible rational zeros of f (x) = x 4 – 12x 2 – 15x – 4. Then determine which, if any, are zeros. A. B. C. D. Example 1
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List all possible rational zeros of f (x) = x 4 – 12x 2 – 15x – 4
List all possible rational zeros of f (x) = x 4 – 12x 2 – 15x – 4. Then determine which, if any, are zeros. A. B. C. D. Example 1
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Leading Coefficient not Equal to 1
List all possible rational zeros of f (x) = 2x 3 – 5x 2 – 28x Then determine which, if any, are zeros. Step 1 The leading coefficient is 2 and the constant term is 15. Possible rational zeros: Example 2
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Leading Coefficient not Equal to 1
Step 2 By synthetic substitution, you can determine that x = –3 is a rational zero. Testing each subsequent possible zero on the depressed polynomial, you can determine that x = 5 and are also rational zeros. By the division algorithm, f (x) = (x + 3)(x – 5)(2x – 1) so the rational zeros are x = –3, x = 5, and Check this result by graphing. Example 2
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Leading Coefficient not Equal to 1
Answer: Example 2
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Leading Coefficient not Equal to 1
Answer: Example 2
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List all possible rational zeros of f (x) = 4x 3 – 20x 2 + x – 5
List all possible rational zeros of f (x) = 4x 3 – 20x 2 + x – 5. Then determine which, if any, are zeros. A. B. C. D. Example 2
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List all possible rational zeros of f (x) = 4x 3 – 20x 2 + x – 5
List all possible rational zeros of f (x) = 4x 3 – 20x 2 + x – 5. Then determine which, if any, are zeros. A. B. C. D. Example 2
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Solve a Polynomial Equation
WATER LEVEL The water level in a bucket sitting on a patio can be modeled by f (x) = x 3 + 4x 2 – 2x + 7, where f (x) is the height of the water in millimeters and x is the time in days. On what day(s) will the water reach a height of 10 millimeters? Because f (x) represents the day when the water level, you need to solve f (x) = 10 to determine what day the water will reach a height of 10 millimeters. Example 3
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f (x) = 10 Write the equation.
Solve a Polynomial Equation f (x) = 10 Write the equation. x3 + 4x2 – 2x + 7 = 10 Substitute x3 + 4x2 – 2x + 7 for f (x). x3 + 4x2 – 2x – 3 = 0 Subtract 10 from each side. Apply the Rational Zeros Theorem to this new polynomial function, f (x) = x3 + 4x2 – 2x – 3. Step 1 Possible rational zeros: factors of –3 = ±1, ±3. Example 3
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Solve a Polynomial Equation
Step 2 Because the number of the day cannot be negative, check each of the positive rational zeros using synthetic substitution. Doing so, you can determine that x = 1 is the only positive rational zero of f. –2 –3 Because x = 1 is a zero of f, x = 1 is a solution of f (x) = 0. So, it was day 1 when the water reached a height of 10 millimeters. Answer: Example 3
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Solve a Polynomial Equation
Step 2 Because the number of the day cannot be negative, check each of the positive rational zeros using synthetic substitution. Doing so, you can determine that x = 1 is the only positive rational zero of f. –2 –3 Because x = 1 is a zero of f, x = 1 is a solution of f (x) = 0. So, it was day 1 when the water reached a height of 10 millimeters. Answer: day 1 Example 3
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PHYSICS The path of a ball is given by the function f (x) = –4
PHYSICS The path of a ball is given by the function f (x) = –4.9x x + 40, where x is the time in seconds and f (x) is the height above the ground in meters. After how many seconds will the ball reach a height of 25 meters? A. 4 seconds, 10 seconds B. 4 seconds C. 5 seconds, seconds D. 5 seconds Example 3
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PHYSICS The path of a ball is given by the function f (x) = –4
PHYSICS The path of a ball is given by the function f (x) = –4.9x x + 40, where x is the time in seconds and f (x) is the height above the ground in meters. After how many seconds will the ball reach a height of 25 meters? A. 4 seconds, 10 seconds B. 4 seconds C. 5 seconds, seconds D. 5 seconds Example 3
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Key Concept 2
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Use the Upper and Lower Bound Tests
Determine an interval in which all real zeros of f (x) = x 4 – 4x 3 – 11x 2 – 4x – 12 must lie. Explain your reasoning using the upper and lower bound tests. Then find all the real zeros. Step 1 Graph f (x). From this graph, it appears that the real zeros of this function lie in the interval [–3, 7]. Example 4
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Step 2 Test a lower bound of c = –3 and an upper bound of c = 7.
Use the Upper and Lower Bound Tests Step 2 Test a lower bound of c = –3 and an upper bound of c = 7. –3 1 –4 –11 –4 –12 –3 21 –30 102 1 –7 10 –34 90 Values alternate signs in the last line, so –3 is a lower bound. 7 1 –4 –11 –4 –12 Values are all nonnegative in last line, so 7 is an upper bound. Example 4
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Step 3 Use the Rational Zero Theorem.
Use the Upper and Lower Bound Tests Step 3 Use the Rational Zero Theorem. Possible rational zeros: Factors of 12 = ±1, ±2, ±3, ±4 , ±6, ±12 . Because the real zeros are in the interval [–3, 7], you can narrow this list to just –1, –2, –3, 1, 2, 3, 4, and 6. From the graph it appears that only –2 and 6 are reasonable. Example 4
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Now test –2 in the depressed polynomial.
Use the Upper and Lower Bound Tests Begin by testing 6. 6 1 –4 –11 –4 –12 Now test –2 in the depressed polynomial. – –2 0 –2 Example 4
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Use the Upper and Lower Bound Tests
By the division algorithm, f (x) = (x – 6)(x + 2)(x 2 + 1). Notice that the factor x has no real zeros associated with it because x = 0 has no real solutions. So f has two real solutions that are both rational, x = –2 and x = 6. The graph of f (x) = x 4 – 4x 3 – 11x 2 – 4x – 12 supports this conclusion. Answer: Example 4
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Use the Upper and Lower Bound Tests
By the division algorithm, f (x) = (x – 6)(x + 2)(x 2 + 1). Notice that the factor x has no real zeros associated with it because x = 0 has no real solutions. So f has two real solutions that are both rational, x = –2 and x = 6. The graph of f (x) = x 4 – 4x 3 – 11x 2 – 4x – 12 supports this conclusion. Answer: Upper and lower bounds may vary. Sample answer: [–3, 7]; With synthetic division, the values alternate signs when testing –3, and are all nonnegative when testing 7. So, –3 is a lower bound and 7 is an upper bound. The zeros are –2 and 6. Example 4
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Determine an interval in which all real zeros of f (x) = 2x 4 – 5x 3 – 13x x – 10 must lie. Then find all the real zeros. A. [0, 4]; 1, 2 B. [–1, 2]; 1, C. [–3, 5]; 1, D. [–2, 1]; 1, Example 4
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Determine an interval in which all real zeros of f (x) = 2x 4 – 5x 3 – 13x x – 10 must lie. Then find all the real zeros. A. [0, 4]; 1, 2 B. [–1, 2]; 1, C. [–3, 5]; 1, D. [–2, 1]; 1, Example 4
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Key Concept 3
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Examine the variations of sign for f (x) and for f(–x).
Use Descartes’ Rule of Signs Describe the possible real zeros of f (x) = x 4 – 3x 3 – 5x 2 + 2x + 7. Examine the variations of sign for f (x) and for f(–x). f (x) = x4 – 3x3 – 5x2 + 2x + 7 + to – – to + f(–x) = (–x)4 – 3(–x)3 – 5(–x)2 + 2(–x) + 7 + to – – to + = x 4 + 3x 3 – 5x 2 – 2x + 7 Example 5
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Use Descartes’ Rule of Signs
The original function f (x) has two variations in sign, while f (–x) also has two variations in sign. By Descartes' Rule of Signs, you know that f (x) has either 2 or 0 positive real zeros and either 2 or 0 negative real zeros. Answer: Example 5
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Answer: 2 or 0 positive real zeros, 2 or 0 negative real zeros
Use Descartes’ Rule of Signs The original function f (x) has two variations in sign, while f (–x) also has two variations in sign. By Descartes' Rule of Signs, you know that f (x) has either 2 or 0 positive real zeros and either 2 or 0 negative real zeros. Answer: 2 or 0 positive real zeros, 2 or 0 negative real zeros Example 5
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Describe the possible real zeros of g (x) = –x 3 + 8x 2 – 7x + 9.
A. 3 or 1 positive real zeros, 1 negative real zero B. 3 or 1 positive real zeros, 0 negative real zeros C. 2 or 0 positive real zeros, 0 negative real zeros D. 2 or 0 positive real zeros, 1 negative real zero Example 5
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Describe the possible real zeros of g (x) = –x 3 + 8x 2 – 7x + 9.
A. 3 or 1 positive real zeros, 1 negative real zero B. 3 or 1 positive real zeros, 0 negative real zeros C. 2 or 0 positive real zeros, 0 negative real zeros D. 2 or 0 positive real zeros, 1 negative real zero Example 5
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Key Concept 4
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Key Concept 5
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f (x) = a[x – (–1)](x – 2)[x – (2 – i)](x – (2 + i)]
Find a Polynomial Function Given Its Zeros Write a polynomial function of least degree with real coefficients in standard form that has –1, 2, and 2 – i as zeros. Because 2 – i is a zero and the polynomial is to have real coefficients, you know that 2 + i must also be a zero. Using the Linear Factorization Theorem and the zeros –1, 2, 2 – i, and 2 + i, you can write f (x) as follows: f (x) = a[x – (–1)](x – 2)[x – (2 – i)](x – (2 + i)] Example 6
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f (x) = (1)(x + 1)(x – 2)[x – (2 – i)][x – (2 + i)] Let a = 1.
Find a Polynomial Function Given Its Zeros While a can be any nonzero real number, it is simplest to let a = 1. Then write the function in standard form. f (x) = (1)(x + 1)(x – 2)[x – (2 – i)][x – (2 + i)] Let a = 1. = (x2 – x – 2)(x2 – 4x + 5) Multiply. = x4 – 5x3 + 7x2 + 3x – 10 Multiply. Therefore, a function of least degree that has –1, 2, and 2 – i as zeros is f (x) = x4 – 5x3 + 7x2 + 3x – 10 or any nonzero multiple of f (x). Answer: Example 6
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f (x) = (1)(x + 1)(x – 2)[x – (2 – i)][x – (2 + i)] Let a = 1.
Find a Polynomial Function Given Its Zeros While a can be any nonzero real number, it is simplest to let a = 1. Then write the function in standard form. f (x) = (1)(x + 1)(x – 2)[x – (2 – i)][x – (2 + i)] Let a = 1. = (x2 – x – 2)(x2 – 4x + 5) Multiply. = x4 – 5x3 + 7x2 + 3x – 10 Multiply. Therefore, a function of least degree that has –1, 2, and 2 – i as zeros is f (x) = x4 – 5x3 + 7x2 + 3x – 10 or any nonzero multiple of f (x). Answer: Sample answer: f (x) = x4 – 5x3 + 7x2 + 3x – 10 Example 6
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Write a polynomial function of least degree with real coefficients in standard form that has –2 (multiplicity 2), 0, and 3i as zeros. A. f (x) = x 5 + 4x x x x B. f (x) = x 5 + 4x 4 + 9x x C. f (x) = x 3 + 2x 2 – 3ix 2 – 6xi D. f (x) = x 4 + 4x 3 – 5x 2 – 36x – 36 Example 6
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Write a polynomial function of least degree with real coefficients in standard form that has –2 (multiplicity 2), 0, and 3i as zeros. A. f (x) = x 5 + 4x x x x B. f (x) = x 5 + 4x 4 + 9x x C. f (x) = x 3 + 2x 2 – 3ix 2 – 6xi D. f (x) = x 4 + 4x 3 – 5x 2 – 36x – 36 Example 6
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Key Concept 6
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k (–x) = (–x)5 + (–x)4 – 13(–x)3 – 23(–x)2 – 14(–x) – 24
Factor and Find the Zeros of a Polynomial Function A. Consider k (x) = x5 + x4 – 13x3 – 23x2 – 14x – 24. Write k (x) as the product of linear and irreducible quadratic factors. The possible rational zeros are ±1, ±2, ±3, ±4, ±6, ±8, ±12, ±24. The original polynomial has 1 sign variation. k (–x) = (–x)5 + (–x)4 – 13(–x)3 – 23(–x)2 – 14(–x) – 24 = –x 5 + x x 3 – 23x x – 24 k(–x) has 4 sign variations, so k (x) has 1 positive real zero and 4, 2, or 0 negative real zeros. Example 7
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Factor and Find the Zeros of a Polynomial Function
The graph shown suggests 4 as one real zero of k (x). Use synthetic substitution to test this possibility. Example 7
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Factor and Find the Zeros of a Polynomial Function
4 1 1 –13 –23 –14 –24 Because k (x) has only 1 positive real zero, you do not need to test any other possible positive rational zeros. The graph suggests that –2 and –3 are negative real zeros. Test these possibilities successively in the depressed quartic and then cubic polynomials. Example 7
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–3 1 3 1 3 Now test –3 in the depressed polynomial. –3 0 –3 1 0 1 0
Factor and Find the Zeros of a Polynomial Function – Begin by testing –2. –2 –6 –2 –6 – Now test –3 in the depressed polynomial. –3 0 –3 The remaining quadratic factor (x 2 + 1) yields no real zeros and is therefore irreducible over the reals. So, k (x) written as a product of linear and irreducible quadratic factors is k (x) = (x – 4)(x + 2)(x + 3)(x 2 + 1). Example 7
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Factor and Find the Zeros of a Polynomial Function
Answer: Example 7
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Answer: k (x) = (x – 4)(x + 2)(x + 3)(x2 + 1)
Factor and Find the Zeros of a Polynomial Function Answer: k (x) = (x – 4)(x + 2)(x + 3)(x2 + 1) Example 7
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Factor and Find the Zeros of a Polynomial Function
B. Consider k (x) = x5 + x4 – 13x3 – 23x2 – 14x – 24. Write k (x) as the product of linear factors. You can factor x by writing the expression first as a difference of squares or x 2 – i 2. Then factor this difference of squares as (x – i)(x + i). So, k (x) written as a product of linear factors is k (x) = (x – 4)(x + 2)(x + 3)(x + i)(x – i). Answer: Example 7
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Answer: k (x) = (x – 4)(x + 2)(x + 3)(x + i)(x – i)
Factor and Find the Zeros of a Polynomial Function B. Consider k (x) = x5 + x4 – 13x3 – 23x2 – 14x – 24. Write k (x) as the product of linear factors. You can factor x by writing the expression first as a difference of squares or x 2 – i 2. Then factor this difference of squares as (x – i)(x + i). So, k (x) written as a product of linear factors is k (x) = (x – 4)(x + 2)(x + 3)(x + i)(x – i). Answer: k (x) = (x – 4)(x + 2)(x + 3)(x + i)(x – i) Example 7
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Factor and Find the Zeros of a Polynomial Function
C. Consider k (x) = x 5 + x 4 – 13x 3 – 23x 2 – 14x – 24. List all the zeros of k (x). Because the function has degree 5, by the corollary to the Fundamental Theorem of Algebra k (x) has exactly five zeros, including any that may be repeated. The linear factorization gives us these five zeros: 4, –2, –3, –i, and i. Answer: Example 7
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Factor and Find the Zeros of a Polynomial Function
C. Consider k (x) = x 5 + x 4 – 13x 3 – 23x 2 – 14x – 24. List all the zeros of k (x). Because the function has degree 5, by the corollary to the Fundamental Theorem of Algebra k (x) has exactly five zeros, including any that may be repeated. The linear factorization gives us these five zeros: 4, –2, –3, –i, and i. Answer: 4, –2, –3, –i, i Example 7
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A. (x + 1)(x – 1)(x + (2 – i))(x + (2 + i))
Write k (x) = x 4 – 4x 3 + 4x 2 + 4x – 5 as the product of linear factors. A. (x + 1)(x – 1)(x + (2 – i))(x + (2 + i)) B. (x + 1)(x – 1)(x 2 – 4x + 5) C. (x + 1)(x – 1)(x – (2 + i))(x – (2 – i)) D. (x + 1)(x – 1)(x + 5) Example 7
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A. (x + 1)(x – 1)(x + (2 – i))(x + (2 + i))
Write k (x) = x 4 – 4x 3 + 4x 2 + 4x – 5 as the product of linear factors. A. (x + 1)(x – 1)(x + (2 – i))(x + (2 + i)) B. (x + 1)(x – 1)(x 2 – 4x + 5) C. (x + 1)(x – 1)(x – (2 + i))(x – (2 – i)) D. (x + 1)(x – 1)(x + 5) Example 7
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Use synthetic substitution to verify that 2 + 5i is a zero of p (x).
Find the Zeros of a Polynomial When One is Known Find all complex zeros of p (x) = x 4 – 6x x 2 – 50x – 58 given that x = 2 + 5i is a zero of p. Then write the linear factorization of p (x). Use synthetic substitution to verify that 2 + 5i is a zero of p (x). 2 + 5i 1 –6 35 –50 –58 (2 + 5i)(–4 + 5i) = –8 – 10i + 25i 2 2 + 5i –33 – 10i = –8 – 10i + 25(–1) 1 –4 + 5i = –33 – 10i Example 8
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Find the Zeros of a Polynomial When One is Known
2 + 5i 1 –6 35 –50 –58 (2 + 5i)(2 – 10i) = 4 – 10i – 50i2 2 + 5i –33 – 10i 54 – 10i = 4 – 10i – 50(–1) 1 –4 + 5i 2 – 10i = 54 – 10i 2 + 5i 1 –6 35 –50 –58 (2 + 5i)(4 – 10i) = 8 – 50i 2 2 + 5i –33 – 10i 54 – 10i 58 = 8 – 50(–1) 1 –4 + 5i 2 – 10i 4 – 10i 0 = 58 Example 8
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Find the Zeros of a Polynomial When One is Known
Because x = 2 + 5i is a zero of p, you know that x = 2 – 5i is also a zero of p. Divide the depressed polynomial by 2 – 5i. 2 – 5i 1 –4 + 5i 2 – 10i 4 – 10i 2 – 5i –4 + 10i –4 + 10i 1 –2 –2 0 Using these two zeros and the depressed polynomial from this last division, you can write p (x) = [x – (2 + 5i)][x – (2 – 5i)](x 2 – 2x – 2). Example 8
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Find the Zeros of a Polynomial When One is Known
Because p (x) is a quartic polynomial, you know that it has exactly 4 zeros. Having found 2, you know that 2 more remain. Solve the remaining depressed polynomial, x 2 – 2x – 2, using the Quadratic Formula. Quadratic Formula a = 1, b = –2, and c = –2 Simplify. Simplify. Example 8
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Find the Zeros of a Polynomial When One is Known
Therefore, the four zeros of p are 2 + 5i, 2 – 5i, The linear factorization of p is p (x) = [x – (2 + 5i)](x – (2 – 5i)][x – ( )][x – ( )]. Using the graph of p, you can verify that the function has two real zeros at or 2.73 and at or –0.73. Example 8
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Find the Zeros of a Polynomial When One is Known
Answer: Example 8
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Find the Zeros of a Polynomial When One is Known
Answer: 2 + 5i, 2 – 5i, , ; p(x) = [x – (2 + 5i)][x – (2 – 5i)][x – ( )] ● [x – (1 – )] Example 8
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Find all complex zeros of h(x) = x 4 + x 3 – 3x 2 + 9x – 108 given that x = –3i is a zero of h.
A. 3i, –3i B. 3i, 4, –3 C. 3i, –3i, 4, –3 D. 3i, –3i, –4, 3 Example 8
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Find all complex zeros of h(x) = x 4 + x 3 – 3x 2 + 9x – 108 given that x = –3i is a zero of h.
A. 3i, –3i B. 3i, 4, –3 C. 3i, –3i, 4, –3 D. 3i, –3i, –4, 3 Example 8
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Practice 2- 4 Homework 2-4 # 1 – 55 odd, 95-98
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End of the Lesson
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